Xerographic cleaning apparatus



April 30, 1968 R. H. EICHORN XEROGRAPHIC CLEANING APPARATUS 10 Sheets-Sheet 1 Filed Oct. 22, 1965 FIG. 1

INVENTOR- ROGER H. EICHORN April 30, 1968 R. H. EICHORN 13,380,355

XEROGRAPHIC CLEANING APPARATUS Filed on. 22, 1965 1o Sheets-Sheet 2 INVENTOR. ROGER H. EICHORN FIG. 2

A T TORIVEVS April 1968 R. H. EICHORN 3,380,355

XBROGRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 I 10 Sheets-Sheet INVENTOR. ROGER H.E|CHORN ATTORNEYS April 30, 1968 R. H. EICHORN 3,330,355

XBRO GRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 10 Sheets-Sheet 4 INVENTOR. ROGER H.'EICHORN IIHIIH IIIH] IIIHI HBIT Elli

IILHII April 30, 1968 R. H. EICHORN XEROGRAPHIC CLEANING APPARATUS l0 Sheets-Sheet 5 Filed Oct. 22, 1965 vkm April 30, 1968 R. H. EICHORN 3,330,355

XEROGRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 10 Sheets-Sheet q A INVENTOR.

ROGER H. EICHORN A 7' TORNEYS A ril 30, 1968 R. H. EICHORN 3,380,355

XEROGRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 10 Sheets-Sheet 7 FIG. 9

' INVENTOR. ROG-ER H. EICHORN April 30, 1968 R. H. EICHORN 3,380,355

xsnoesmraxc CLEANING APPARATUS Filed 001;. 22, 1965 1o Sheets-Sheet a mvsw'roa ROGER H. EICHORN April 30, 1968 R. H. EICHORN 3,330,355

XEROGRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 1o Sheets-Sheet 9 INVENTOR- ROGER H. EICHORN A T TORNEVS April 30, 1968 R. H. EICHORN 3,380,355

I XEROGRAPHIC CLEANING APPARATUS Filed Oct. 22, 1965 10 Sheets-Sheet 10 LMP- l LMP-I FIG. 12

I ICRB 5LS-B TLS '1 1L I IGR mcR-l fsLs-A gfeLs n MOT-l MOT*2/\ l ON LM% W ILS 2L8 3L8 12o VOLTS INVENTOR. ROGER H. EICHORN A T TORNEKS United States Patent 3,380,355 XEROGRAPHIC CLEANING APPARATUS Roger H. Eichom, Webster, N.Y., assignor to Xerox Corporation. Rochester, N.Y., a corporation of New York Filed Oct. 22, 1965, Ser. No. 504,288 1 Claim. (Cl. 95-1.7)

This invention relates to xerographic drum cleaning apparatus and particularly to apparatus to clean residual powder from the surface of a xerographic drum.

More specifically, the invention relates to improvement in apparatus for removing residual powder images from the surface of a rotating Xerographic drum in an automatic Xerographic machine. A Xerographic plate or drum is composed of a layer of photoconductive insulating material mounted on a conductive backing, usually metal. A uniform electrostatic charge is applied to the photoconductive surface, and the surface is then exposed to a light image of the subject matter to be reproduced. This exposure discharges areas of the drum or plate in accordance with the radiation intensity that reaches them and thereby creates an electrostatic latent image of the copy being reproduced on or in the photoconductive layer. Development of the latent image is effected with an electrostatically charged, finely divided material such as an electroscopic powder that is brought into surface contact with the photoconductive layer and is held thereon electr-ostatically in a pattern corresponding to the electrostatic latent image. Thereafter, the developed xerographic powder image is usually transferred to a support surface to which it may be fixed by any suitable means. The electroscopic powder or toner material, as it is commonly referred to in the art, is usually composed of a pigmented resinous material having suitable physical properties necessary to permit fusing of the powder to the surface of the support material to which it is transferred and to permit the creation of a triboelectric charge when the powder is agitated in contact with a carrier bead.

After the transfer of a power image from the drum to a support surface, there is usually a residue of unremoved developer powder, usually in image configuration and referred to in the art as a residual powder image. Before the drum can be reused for a subsequent cycle, it is necessary to remove the residual image to prevent ghosting on subsequent copies. In automatic xerographic equipment, the xerographic drum is continuously rotated through cycles of sequential operations including the charging, exposure, developing and transfer cycle. After each transfer operation, it is necessary that the plate be cleaned, preparatory to receiving a new image for subsequent transfer.

It is usual to charge the plate with a corona of positive polarity by means of a corotron or corona charging device of the type disclosed in Walkup Patent 2,777,957.

Development of an electrostatic latent image forms a powder image on the plate which is electrostatically trans ferred to the support surface by means of a corotron or corona generating device such as mentioned above. In automatic machines, the support surface to which the powder image is to be transferred must move in contact with the Xerographic drum at the same speed as the drum so that the powder image may be transferred thereto without any smearing or misalignment of the image. Transfer is effected by the corona generating device which imparts an electrostatic charge to the back of the support material surface to attract the powder from the drum to the support surface. It is usual to employ a developing material which is triboelectrically charged to a negative polarity and to apply an original charge to the surface of the xerographic drum of a positive polarity so that the negatively charged powder is attracted to the drum in the image areas. After formation of the powder image, a

second charge of positive polarity is placed on the back of the sheet of support material so that the negatively charged powder is attracted to the support surface. It is desirable to neutralize the charge remaining on the surface of the plate after transfer but prior to cleaning the plate. To accomplish this, a corona generating device applies a negative charge to the surface of the drum to counteract the previous positive charge holding the powder on the surface of the drum. This procedure is intended to simplify the removal of the powder from the drum surface by the cleaning apparatus.

In Patent Number 3,141,398 in the name of Graft et al., there is disclosed an improved method and apparatus for cleaning residual powder from a xerographic plate. As disclosed in this application, removal of residual powder is effected by rubbing against the drum surface a web of fibrous material such as, for example, paper toweling, cheesecloth, flannel and cotton fiber impregnated with a resin of urea formaldehyde. These inexpensive and exposable webs of fibrous material are advanced into pressure and rubbing contact with the xerographic plate and are gradually and continually advanced to present a clean surface to the plate whereby complete removal of residual powder from the plate is effected.

It is an object of this invention to improve web cleaning apparatus used for removing residual powder images from a xerographic plate.

Another object of this invention is to improve web cleaning apparatus in a manner to increase the efficiency of the cleaning operation.

It is a further object of this invention to improve web cleaning apparatus to continuously supply clean web to the surface of a rotating xerographic drum.

These and other objects of this invention are attained by means of a Web advancing mechanism mounted on a cleaning roller urging the web into contact with the sur face of the Xerographic drum and a similar Web ad vancing means attached to a web take-up roller in the web cleaning unit.

For a better understanding of the invention as well as other objects and further features thereof, reference is had to the following detailed description of the invention to be read in connection with the accompanying drawings, wherein:

FIG. 1 is a perspective view of a Xerographic machine embodying the present invention;

FIG. 2 is a schematic side sectional view of the machine shown in FIG. 1 showing the operation of the machine;

FIG. 3 is a perspective view of the xerographic drum, developer unit and toner dispenser of the Xerographic machine shown in FIG. 1, with portions broken away to show internal construction;

FIG. 4 is a front view of the toner dispenser shown in FIG. 3;

FIG. 5 is a rear view of the document conveyor taken along lines 5-5 of FIG. 2 with portions broken away to show internal construction;

FIG. 6 is a side view of the document conveyor taken along lines 6-6 of FIG. 5;

FIG. 7 is a right-hand side view of the apparatus shown in FIG. 1 with the outside cover removed;

FIG. 8 is a right-hand sectional view taken along lines 8--8 shown in FIG. 9;

FIG. 9 is a front sectional view taken along lines 9-9 of FIG. 7;

FIG. 10 is a perspective view of the main drive shaft and control elements shown in FIG. 9;

FIG. 11 is a right-hand sectional view of the web cleaning apparatus taken along lines 11-11 of FIG. 9;

and

FIG. 12 is a schematic wiring diagram of the apparatus shown in FIG. 1. r

The xerographie machine shown in FIG. 1 consists of a pair of side covers and 12 and the top cover 14. The front of the machine has an opening 16 to receive an original document to be reproduced, and an opening 18 into which copy paper or support material is fed to receive a powder image. After an image has been transferred to the copy paper, the paper emerges from a slot 20 in the top cover 14.

As seen in FIG. 2, a xerographic drum 22 having a layer of photoconductive material 23 about its outer surface is mounted for rotation on a shaft 24. As the drum 22 rotates, it moves past a charging station 26.

wherein a uniform electrostatic charge is placed on the photoconductor 23 by means of a corotron 28. The drum then rotates past an exposure station and a developer station 32. At the developer station 32, a powder image is formed corresponding to a latent electrostatic image created on the drum surface at the exposure station. The light image at exposure station 30 discharges the drum in areas of light and leaves the drum an insulator in areas of darkness thereby creating an electrostatic latent image on the drum surface. As the drum rotates through the developing station 32, a paddle wheel 34 impels developer material 36 against the surface of the drum 22. The developer material is composed of a granulated carrier bead and resinous powder or toner material used to develop the electrostatic images. The toner material is triboelectrically held on the carrier beads and is electrostatically attracted away from the carrier beads to the areas containing the latent electrostatic image, thereby developing a powder image.

The drum continues to rotate past a transfer station 38 having a transfer corotron 40 and a drum cleaning station 42 having a precleaned corotron 44 and a web cleaner 46. The powder image on the drum surface is transferred to a sheet of paper or support material at the transfer station 38. The transfer corotron 40 is positioned to provide an electrostatic charge on the back of a belt 48. The belt 48 is of dielectric material and moves in a continuous loop so that sheets of paper will be carried into contact with the surface of the drum 42. A sheet of paper inserted in the opening 18 is gripped between the belt 48 and a roller. The paper is forced forward past an electrostatic charging device until it trips a switch LS-7. The switch LS-7 turns on the corotron which tacks the paper to the belt. A second or transfer corotron 40 then applies a charge to the back of the belt. The electrostatic charge placed on the back of the belt by the electrostatic charging device or corotron 40 attracts the powder image from the drum surface to the surface of the paper. The paper is then carried forward past a fuser 50 wherein the powder is heated and caused to coalesce and bond to the surface of the paper. The paper is gripped by a pair of ejection rollers 52 and driven forward against a deflection guide 54 which curves the paper upwards and out slot 20 to the top of the machine.

The toner powder used herein has a negative charge relative to the various charges used to create the latent electrostatic images and to transfer the powder from the drum to the support material surface. The latent electrostatic image is created from the positive charge that is placed on the surface of the xerographic drum by the corotron 28. Therefore, the negative charged toner is attracted to the positive latent electrostatic image. At the transfer station, the transfer corotron 40 places another positive charge on the back of the transfer material and the belt 48 so that the negative toner material is then attracted to the surface of support material.

The drum cleaning station 42 has a cleaning roller 56 which forces a web of fibrous material 46 into surface contact with the rotating xerographic drum. The residual powder which has not been transferred to the sheet of paper or support material remains on the drum surface and must be removed prior to the creation of a new image on the surface of the drum. The powder material is held on the drum surface by electrostatic charges which originally were used to create the image and residual electrostatic charges in non-image areas. The effect of these electrostatic charges is neutralized by the use of the preclean corotron 44 which deposits a uniform electrostatic charge of opposite polarity to that holding the toner on the surface of the drum. The fibrous Web material 46 is taken from a supply roll 58 around the cleaning roll 56 into contact with the surface 23 of the drum 22 and onto a take-up roll 60. The actuation of the advancing mechanism for the web cleaner is described below. The surface of the xerographic drum is then exposed to a spot of light 62 which discharges the drum surface, removing any residual electrostatic charges which may exist on the drum surface.

The original copy to be reproduced is positioned on a counter 64 and inserted into the document opening or slot 16. The document slides forward, deflecting switch actuator 66 of a limit switch LS6, until it encounters the document positioning stop 68. With the document abutting against the stop 68, it overlies a feed belt system 70 and is beneath a feed roller 72. When the machine is in operation, as described below, the feed roller 72 comes down on the document, forcing it against the feed belt 70 and driving it forward. The stop 68 which is mounted on a shaft 74 is rotated in a counterclockwise direction as seen in FIG. 2, deflecting the front end of the document down along the path of the feed belt 70. The belts '70 are constructed of a dielectric material and the document is held in contact with the belts 70 by a row of leaf spring-type guides 76 which extend across the conveyor system. The document is electrostatically tacked to the belt 70 by electrostatic charge applied to the document surface by a corotron 78.

The feed roll belts 70 extend around belt rollers 80 and are held in tension by a pair of guide rollers 82, one of which is adjustable to vary the tension on the belts 70. The documents are carried by the belts 70 past scanning station 84 where they are illuminated by a pair of lamps LMP-l. The documents are carried down between the belts 70 and a lower roller 36 at the same speed as the surface of the xerographic drum and then ejected through a slot 88 at the bottom front of the machine. The belts 70 and the documents held thereon are flat against a backup platen 90 at the scanning station. The backup platen 90 is white at the scanning station to reflect any light passing through the document back through the document to the xerographic drum 22. The lamps LMP-l are housed in a housing 92 and shielded from the document by a transparent plate 94.

An optical image of the illuminated portion of the document at the exposure station 84 passes through the transparent plate 94, through an opening 96 in the lamp housing 92 to a combination mirror lens assembly 98. The latent image passes through the lens 102 and is re-. flected by a mirror surface 104 back through the lens 102 to a mirror 106. The lens 102 focuses the image so that the image is properly focused on the drum surface 22 when it is reflected by the mirror 106 through the exposure slit 10 8 at exposure station 30 to the drum surface 22. The light path of the optical image is indicated generally by the dotted line 110.

The xerographic mechanism is shielded from the ambient light produced by the exposure system by means of a shield 112. The light shield 112 has an opening 114 positioned between the mirror 106 and the exposure slit 108 to allow passage of the light image to the drum surface. There is also an opening 116 in the light shield 112 which permits some of the ambient light to pass through the shield and be reflected by a reflective surface 118 to the drum to produce the discharge spot 62. The light of the discharge spot 62 removes any residual charge remaining on the drum surface after drum cleaning by rendering the photoconductive surface conductive and draining off any remaining charge.

The development system used to develop the latent electrostatic images on the side of the drum which is moving from bottom to top is a paddle wheel developer. A rotatable shaft having a series of paddles 122 extending outward from the periphery t-hereof constitutes the paddle wheel 34. The paddle wheel 34 extends across the length of the drum 23 and is contained within the developer hous'ng 124. The developer housing 124 extends from a point just past the exposure station 30 in the direction of movement of the drum to a point further along in the direction of rotation of the drum. The housing is shaped to contain a quantity of developer material 36 in contact with the paddle wheel 34. A developer 36 consists of carrier beads and toner particles intimately mixed so that a triboelectric charge causes the toner particles to adhere to the carrier beads. As the paddle Wheel 34 rotates in the direction indicated by the arrow, the developer material is hurled or thrown by the paddles 122 upwards against the surface 22 of the drum 23. Developer is prevented from passing between the drum surface and edge of the developer housing 124 by means of a drum seal 126. The seal 126 consists of a piece of Mylar mounted on the edge of the housing 124 in contact with the surface of the xerographic drum.

As the developer encounters the surface of the drum, portions of the toner material are jarred loose from the carrier beads and are attracted by electrostatic charges on the drum surface. The electrostatic charges on the drum surface define the images to be produced, and thus the powder particles held on the drum surface by the electrostatic charge are in image configuration. The carrier beads continue upward in their path of travel and eventually fall back into the lower portion of the developer housing 124 to be remixed with the main body of developer mate rial. As toner particles are removed by the electrostatic charge on the drum surface, additional toner must be added to the main body of developer material. A toner dispenser 128 is mounted in the top of the developer housing 124 for the purpose of supplying additional toner material as needed. The toner dispenser 128 consists of a container portion 130 adapted to hold solid blocks of toner material 132, a pressure cap 134 and a scrapping blade 136. The blocks of toner 132 are placed in the container 130 with one edge against the blades 136. The cap 134 is also placed inside the container 130 against the blocks 132 and is held in place and forced forward by a series of leaf springs 138. The leaf springs 138 are mounted on brackets 140 on the front cover 142 of the apparatus. As the cover 142 is closed, the leaf spring 140 is forced against the cap 134 urging the solid blocks of toner 132 against the blades 136.

Operation of the toner dispenser can best be seen in FIGS. 3 and 4. The blades 136 are similar to hack saw blades bent in a honeycomb configuration to insure complete coverage of the surface of the toner blocks and mounted in a pair of end blocks 144. The end blocks 144 are supported in the machine frame plate by means of a pair of sliding pins 146 at one end and a single pin number 148 at the other end. The pin 148 has a button or cap 150 counted on one end so that it extends outside of the entire machine. A compression spring 152 is mounted on the shaft 148 between the cap 150 and a bearing plate 154. Pressure on the cap 152 forces the pin 148 and the blades 136 forward against the action of the spring 152. The movement of the blades 136 across the surface of the block 132 produces a scrapping action which removes portions of the toner material from the block which then fall into the bottom of the developer housing 124. When the cap 150 is released, the spring 152 returns the springs 13-6 to their original position again producing a scrapping action on the surface of the blocks 132 and removi toner therefrom.

A conveyor belt 48 is positioned to carry a sheet of paper from the copy paper opening 18 into contact with the xerographic drum 23 and then to the fuser 50 and ejection rollers 52. The belt 48 extends around a roller 156 just inside the copy paper opening 18 and a spring loaded tensioning roller 158 positioned just ahead of the heat fuser 50. As the belt extends between the rollers 156 and 158, the bottom surface thereof is in contact with the the top of the Xerographic drum 23. The roller 158 is journaled in a bifurcated member 160 and is spring loaded by compression spring 162. The bifurcated member 160 is mounted on and pivoted about a shaft 164 so that rotation of the shaft 164, as described below, will elevate the roller 158 and the belt system 148 away from the drum 23. When a sheet of paper is inserted in the opening 18 on counter 166, it slides forward until it is gripped between a pressure roller 168 and the belt 48 at roller 156. The paper is carried forward in contact with the belt to a point just beyond an electrostatic discharge member or corotron 172. The belt 48 is held flat at this point by a guide 170 mounted against the inside surface of the belt. The corotron 172 is energized when the paper hits switch LS-7 and placed an electrostatic charge on the paper surface, in this case, a positive charge, causing the paper to adhere to the belt. The electrostatic attraction between the paper and the belt causes the paper to be carried forward with the belt into surface contact with the xerographic drum. When the paper has been in contact with the xerographic drum and had a powder image transferred thereto, it is carried forward to the heat fuser 50 and is separated from the belt 48 by the sharpness of the angle that the belt takes around the roller 158. The sharpness of the angle and the natural rigidity of the paper are sufficient to overcome the electrostatic attraction between the belt and the paper, and thus the paper continues forward while the belt is directed around the roller 158.

The transfer corotron 40 mounted above the belt 48 at the top of the drum or transfer point 38 is tilted at a slight angle such that the electrostatic charges placed on the belt directly above the transfer point and not preceding the transfer point. When the electrostatic charge is placed on the belt slightly before the transfer point, the elect-ostatic image on the drum surface tends to produce an are between the drum and the belt; and the powder image on the drum surface is disrupted or destroyed. Tilting the transfer corotron 40 in the manner shown in FIG. 2 eliminates the arcing prior to the transfer process.

Operation The apparatus is driven by a motor MOT-1, as seen in FIGS. 7 through 9, through a gear box 174 to a main drive shaft 175. The drive shaft 175 extends outward from the gear box 174 through a side frame plate 178 and has a pulley 176 mounted thereon. The pulley 178 drives a timing belt 180 which extends around tensioning idling pulleys 182 to a drum drive pulley 184.

A second drive shaft 26 also extends out of the gear box 174 through the side frame 178 terminating in pulley 188. The pulley 188 drives a timing belt 190 which extends around a pulley 192 on the developer drive shaft 120. The shaft 120 extends through the developer housing 124 and supports the paddle blades 122 in the developer housing.

A pulley 196 mounted on a shaft 198 is driven by the main drive belt 184 and drives the document conveyor belt 70. The shaft 198 supports the lower belt roller 80 of the document conveyor. A gear 202 mounted on the shaft 198 drives a gear 204 on the shaft 207 of the roller 86. As seen in FIG. 5, the shaft 198 also supports a pair of platen support members 206. The platen support members 206 support and position the backup platen 90 and also provides support for the shaft 208 of the other belt roller 80. Both shafts 198 and 207 are journaled in a second side frame 210 and an intermediate support frame member 212.

The final pulley 214 driven by the timing belt 180 is mounted on an intermediate shaft 216 supported between the side frame plates 17 8 and the intermediate frame plate 212. Power is transmitted from the belt 180 to the pulley 214 to the shaft 216 and then to a pulley 218 also mounted on the shaft 216 and driving a belt 220. The belt 220 drives another pulley 222 on the shaft 224 of the roller 226 of the ejection rollers 52. Therefore, when the main drive motor MOT-1 is running, the timing belt 180, the drum drive pulley 184, the document conveyor, and the ejection rollers 52 are all being driven. Operation of the main drive motor MOT-1 also effects operation of the developer paddles 122.

The drum drive pulley 184 is mounted on a hollow shaft 228, journaled in bearings 231) in the side frame 178 and the intermediate support frame 212. The shaft 228 is releasably connected to the xerographic drum shaft 232 and transmits rotational movement from the pulley 184 to the drum 22. The shaft 228 also supports a torque tube 234. The torque tube 234 is mounted on the shaft 228 by means of a pair of bearings 236 and 238. The torque tube 234 is driven from the shaft 228 by a gear train indicated generally as 240 and consisting of a first gear 242 secured to the shaft 228 and meshing with a larger gear 244 mounted on and secured to a rotatable bearing 246 on a stub shaft 248 extending inwardly from the side frame plate 178. The gear 244 produces rotation of the bearing 246 and a smaller gear 250. The gear 250 meshes with gear 252 secured to the torque tube 234. The transmission of power from the shaft 228 through the gear train 240 to the torque tube 234 produces rotation of the torque tube at a rate that is one-half of the rotational movement of the Xerographic drum 22. That is, the shaft 228 rotates through two complete revolutions as the torque tube 234 rotates through one complete revolution.

The torque tube 234 supports a series of cams used to control the operation of the various components of the machine. A double cam 254 is used to actuate a switch arm 256 for switch LS5. The cams 254 may be adjusted by rotating the cams relative to each other to vary the timing of the operation of the switch LS-S. The cams 254 are secured to the torque tube 234 by means of a hub 258. A second cam 260 is also mounted on the torque tube 234 and operates a follower 262 on arm 264. The arm 264 is secured to shaft 164. The cam 260 produces a turning motion of the arm 264 which in turn rotates the shaft 164 against the action of torsion spring 266 and raises the roller 158 of the document conveyor. Rotation of the shaft 164 produces a rotational movement of the bifurcated member 160 supporting the member 158 so that the belts 48 are moved away from the xerographic drum 22.

The document feed roller 72 is controlled by a cam 268 mounted on the torque tube 234 and designed to move follower 270 on arm 272. The arm 272 rotates a stub shaft 274 which has a second arm 276 connected thereto. The arm 276 bears against the shaft 278 and produces movement of the shaft in slots 280 in the side frame 210 and the intermediate support frame 212. The shaft 280 is the support shaft for the document feed roller 72. As seen in FIGS. 5 and 8, the shaft 278 is urged in a downward direction by a pair of torsion springs 282, urging the roller 72 into driving contact with the belts 70 of the document conveyor. The rotational movement of the cam 68 forces the follower 270 and the arm 272 downward, pivoting the arm 276 upward urging the shaft 27 8 against the action of the springs 282 and separating the roller 72 from the belt '70. A tension spring 284 urges the follower arm 272 in a direction opposite to the movement produced by the cam 268.

A pair of cams 286 and 288 are secured to a mounting ring 290 on the hub of the cam 268 which in turn is supported from the torque tube 234. A pair of followers 292 and 294 engage the cams 286 and 288, respectively, and move follower arm 296 and 298, respectively. The'cams, followers and arms provide the operation and control of the web cleaner 4-6. As seen in FIG. 11, the follower arm 296 pivots about a shaft 302 and actuates a pawl 304. The follower arm 298 pivots about a shaft 306 and actuates pawl 308. The pawl .304 actuates a ratchet wheel 310 mounted on the shaft 312 which supports the web take-up roll 360. The pawl 308 actuates the ratchet wheel 314 mounted on the front shaft 316 which supports the cleaning roller 56. The two follower arms 296 and 298 are urged towards each other so that the followers 292 and 29-4 ride on the cams 286 and 288 by a tension spring 318. Each of the cams has three lobes or rises which are spaced equal distances about the periphery of the cam. The rises on each cam are staggered with the rises on the other cam so that when one follower is at an elevated position, the other follower is at a depressed position. As the machine rotates, cam 288 elevates the follower 294 and arm 298 so that the pawl 308 actuates the ratchet wheel 314. The ratchet wheel 314 turns the shaft 316 and the cleaning roller 56 so that new web material is advanced from the supply roll 58 into surface contact with the xerographic drum 22. A small pawl 320 also cooperates with the ratchet wheel 314 to prevent movement of the cleaning roll 56 by the xerographic drum 22.

Continued operation of the machine causes the cam 286 to actuate the follower arm 296 and pawl 304 so that the ratchet wheel 310 is advanced one position moving the shaft 312 and the take-up roll 60. This process is repeated three times for each revolution of the torque tube 234. Since the torque tube 234 revolves one-half revolution for every revolution of the xerographic drum 22, the web material 46 is advanced three times for each revolution of the torque tube. A switch LS-4 having an actuating arm 322 which bears against the side of the supply roll 58 indicates when there is a low sup-ply of web material. The actuating arm 322 is biased against the side of the web material; and when the web material has been depleted from the supply roll 58 to a point suflicient to allow the arm 322 to pass, the switch LS-4 is actuated, illuminating lamp LMP-l on the control panel as seen in FIG. 1. The lamp LMP-3 indicates to the operator that th cleaning web should be replaced.

The take-up roll shaft 312 and the supply roll shaft 313 are supported from the intermediate frame plate 212 and a support frame member 319 seen in FIG. 9. The two shafts are supported from the two support members in cantilever fashion so that the rolls of web material may be placed on and taken off of their rolls respectively from the opposite side of the machine. The cleaning roll shaft 316 is supported from the intermediate frame plate 212 and the side frame plate 178 and at the opposite end by means of a repivotable support member 321 which holds the end of the roll during operation and is removable therefrom for purposes of changing the supply of web material. The cleaning roller 56 is pivotable away from the drum so that the web may be inserted between the roller and the drum surface.

The last cam 324, driven by the torque tube 234, is connected to the hub of the cam 268 and regulates the operation of the copy paper pinch roller 168. The operation of the cam 324 and its associated follower 326 and the follower arm 328 can best be seen in FIG. 10. The arm 328 is secured to stub shaft 330 which is rotatably mounted in the intermediate support frame 212. The shaft 33%) also supports sprocket 332 which drives the electrostatic conveyor 48 by means of timing belts 334 which extend around the sprocket 332 and a second sprocket 336. The second sprocket 336 is mounted on shaft 338 which supports the roller 156. Roller 156 drives the belts 48 of the electrostatic convey-or. The sprocket 332 is driven by means of a smaller gear 340 secured to the gear 332 and positioned to engage the segmented gear 342 mounted on the shaft 228. The gear 346 has a positioning member 344 which mates with and permits passage of the portion of the segmented gear which does not have teeth. The member 344 also prevents rotation of the gear 340 during the time it is not meshed with the teeth of the segmented gear 342, thus the conveyor belt 48 cannot be driven during the portion of the cycle in which the teeth of the segmented gear do not mesh with the teeth of the gear 340.

When a sheet of copy paper is inserted into the opening 18, the roller 168 is held separated from the roller 156 and belt 48 by an arm 340 mounted on shaft 330 as seen in FIG. 10. The arm 346 is actuated by the cam 324 through the follower arm 328 and forces the follower 168 downward against the action of spring 348. When a switch LS-7 is stripped by the copy paper, the drive motor is energized as explained "below; and the cam 324 is rotated, raising the arm 346 and permitting the spring 348 to force the roller 168 into driving contact with the belt 48. At the same time, the corotron 172 is energized, electrostatically tacking the copy paper to the belts 48; and the segmented gear 348 rotates to a position wherein the teeth of the gear mesh with the gear 340; and the positioning member 344 permits rotation of the gear 340 so that the belt system is driven through the sprocket 332, belt 334 and sprocket 336 on shaft 338.

The main drive shaft 228 supports the xerographic drum 22 by means of a pair of rotatable plugs 350. The shaft 228 is hollow so that a screw driver may be inserted through the length of the shaft and into the slotted head of one of the plugs 350. The slotted head of the other plug 350 is also accessible to a screw driver. The drum 22 is hollow and adapted to receive a pair of end plates 352. The end plates are held in the drum by means of tie rods 354. A hearing 356 is mounted in one end plate 352 and supports a shaft 358 which extends through the center of the drum and is also journaled in the opposite end plate 352. The shaft 358 is drilled at each end to receive the plugs 350 and compression springs 360. With the plugs 350 inserted into the end of the shaft 358, the drum assembly may be supported by one plug resting in the opening of the shaft 228; and the other plug resting in a bearing 362 in the side frame member. A compression spring 364 mounted around the shaft 358 biases the entire drum assembly towards the left-hand frame member 210 so that the end plate 352 abuts a retaining ring 366 mounted on the shaft 358, thus insuring the proper position of the xerographic drum 22. A pin 368 extends through an opening in the shaft 228 into the plug 350 so that the shaft 358 and the drum assembly 22 rotates with the shaft 228. To remove the drum from the machine, a pair of screw drivers are placed in the slotted ends of the plugs 350; and the plugs are forced inward against the action of springs 360 and rotated 90. A pin 370 in each of the plugs 360 mate with slotted openings 372 in the shaft 358 to permit longitudinal movement of the plugs 350. The rotational movement of the plugs 350 is accomplished by extensions of the opening 372 extending around the circumference of the shaft 358. The openings 372 are in effect L-shaped so that when the plugs 350 are rotated 90, the pins 370 hold the plugs in against the action of springs 360, thus allowing the drum 22 to be removed from the apparatus.

FIG. 12 shows a schematic wiring diagram on the apparatus. The machine operates on a 120-volt circuit and has three interlock switches 1LS, 2LS and 3L5 on the rear, top and front of the machine, respectively, to insure that the covers of the machine are in place and closed before the machine is operated. The switch ZLS can be seen in FIG. 7 at the top of the machine. With the covers in place and the limiting switches lLS, 2LS and 3L5 closed, a transformer T-1 is energized, providing power to a 28-volt circuit. Therefore, when the machine is first plugged in and power supplied to the transformer T-l, a lamp LMP-Z is illuminated on the front of the machine and indicates that the machine is on. A motor MOT-2 is also energized and drives a blower 374, seen in FIG. 7.

The blower 374 exhausts air from the machine and keeps the apparatus cool. A set of normally closed contacts 4LS, corresponding to the limit switch LS-4 located adjacent to the web cleaner supply roll, control the operation of the low web indicator lamp LMP-1 and a solenoid SOL-1 which operates a buzzer which also indicates that the supply of web cleaning material is low. The contacts 4LS are held in the open position by the arm 322. of the switch LS4 when the arm bears against the side of the web cleaning supply roll.

The main drive motor MOT1 is controlled by two normally open sets of contacts 5LSA and 6LS. The contacts 5LS-A are associated with the switch LS-5 actuated by the cam 252 on the main drive shaft 228. When the cam 252 actuates the switch LS-S, the contacts 5LSA close. When a document is inserted into the opening 16, actuating arm 66 and associated switch LS-6, the contacts 6L8 also close, energizing the motor MOT-1 so that the document is advanced into contact with the stop 68; and the cam 25-4 is rotated releasing the switch LS5. Release of the switch LS-S cuts of the motor MOT1 and also permits closing of contacts SLS-B which had been held open during the actuation of the motor MOT-1. Closing of the contacts 5LS-B permits relay ICR to be energized when the switch LS-7 is energized by the copy paper being inserted in the opening 18. Energization of the switch LS7 closes the contacts 7LS, energizing the relay ICR. The relay lCRs first set of contacts. 1CR-1 again energize the motor MOT-1 driving the entire apparatus; and the contacts 1CR-2 and 1CR-3 are also closed. The contacts 1CR-2 bypass the copy contacts 7LS of the copy sensing switch LS-7 so that the relay lCR will remain energized after the copy paper has passed the actuating arm of the switch LS-7. The contacts 1CR-3 permit power to the power supply PS-l which energizes each of the corotrons 40, 26 and 44. The power supply PS-1 also provides for energization of the corotron 172 which is used to electrostatically tack the paper to the conveyor belt 48.

At the same time that the power supply PS-1 is energized, the fuser 50 is also energized; and the illuminating lamps LMP-l are turned on, illuminating the document in the exposure station 84. When the copy paper has released the switch 7LS and the cam 252 has completed a revolution and again actuated switch LS5, the contacts SLS-B open; and the relay 1CR is de-energized, stopping the motor MOT-1 and turning off the power supply PS-l, the fuser 50 and the lamps LMP-l. The machine is then again in a position to be used to reproduce other copies. The length of time for the cam 254 to return to its original position and actuate the switch LS-5 is long enough for the document paper to be carried out the bottom opening 88 by the conveyor belts 70 and the roller 86 and also for the copy paper to be carried past the fuser 50 through the discharge rollers 52 and out the slot onto the top of the machine.

While the invention has been described with reference to the structure disclosed herein, it is not confined to the details set forth; and this application is intended to cover such modifications or changes as may come within the purpose of the improvements or the scope of the following claim.

What is claimed is:

1. In a xerographic reproducing apparatus wherein a xerographic drum is rotated through a series of processing stations including a drum cleaning station having a series of parallel shafts and a web of fibrous material extending from a supply roll mounted on one of the shafts to a take up roll mounted on another of the shafts and urged into rubbing contact with the surface of the xerographic drum by a cleaning roll mounted on another of the shafts, the improvement comprising a first ratchet wheel secured to the shaft of the cleaning roller,

a second ratchet wheel secured to the shaft of the takeup roller, and i 11 12 a first cam and a second cam mounted for rotation pro- References Cited portional to the rotation of the xerographic drum and UNITED STATES PATENTS means operated by the first and second cam to actuate the ratchet wheels sequentially so that the web is 3099856 8/1963 Elchom X advanced by the cleaning roll and then taken up by 5 3,190,198 6/1965 Elchom the take-up roll to thereby continuously supply clean material to the drum surface JOHN M. HORAN, Primary Examiner. 

1. IN A XEROGRAPHIC REPRODUCING APPARATUS WHEREIN A XEROGRAPHIC DRUM IS ROTATED THROUGH A SERIES OF PROCESSING STATIONS INCLUDING A DRUM CLEANING STATION HAVING A SERIES OF PARALLEL SHAFTS AND A WEB OF FIBROUS MATERIAL EXTENDING FROM A SUPPLY ROLL MOUNTED ON ONE OF THE SHAFTS TO A TAKEUP ROLL MOUNTED ON ANOTHER OF THE SHAFTS AND URGED INTO RUBBING CONTACT WITH THE SURFACE OF THE XEROGRAPHIC DRUM BY A CLEANING ROLL MOUNTED ON ANOTHER OF THE SHAFTS, THE IMPROVEMENT COMPRISING A FIRST RATCHET WHEEL SECURED TO THE SHAFT OF THE CLEANING ROLLER, A SECOND RATCHET WHEEL SECURED TO THE SHAFT OF THE TAKEUP ROLLER, AND A FIRST CAM AND A SECOND CAM MOUNTED FOR ROTATION PROPORTIONAL TO THE ROTATION OF THE XEROGRAPHIC DRUM AND MEANS OPERATED BY THE FIRST AND SECOND CAM TO ACTUATE THE RATCHET WHEELS SEQUENTIALLY SO THAT THE WEB IS ADVANCED BY THE CLEANING ROLL AND THEN TAKEN UP BY THE TAKE-UP ROLL TO THEREBY CONTINUOUSLY SUPPLY CLEAN MATERIAL TO THE DRUM SURFACE. 